4094
J . Phys. Chem. 1990, 94, 4094-4099
Infrared Laser Photochemistry of SIH,-CH,CI
Mixtures
C.B. Moore and F. W. Lampe* Department of Chemistry, 152 Davey Laboratory, The Pennsylvania State University, University Park, Pennsylvania 16802 (Received: May 27, 1987; In Final Form: July 17, 1989)
By use of a pulsed C 0 2 TEA laser at 944.19 cm-l and fluences in the range of 0.49-0.71 J/cm2, the infrared photochemistry of SiH,-CH,CI mixtures has been studied in a pressure range of 50-100 Torr and over a temperature range of 295-428 K. The gaseous products observed are H,, CH,, Si2H6,and SiH3CI,with trace amounts of Si,H, and perhaps CH,SiH,CI. As is usual in silane decomposition, a brown solid product containing silicon, hydrogen, and, under some conditions, chlorine was also produced. The photochemical conversion is best described by initial decomposition of SiH, to SiH, and H, followed by competition of SiH, and CH3C1for SiH, molecules. The production of CH4 is believed to occur via the decomposition of highly energized CH3SiH2CI*(formed by SiH, insertion into the C-CI bond of CH3CI),yielding CH, and SiHCl as products. SiH3CI is then formed by the secondary reaction of SiHCl with SiH,. Studies of the temperature dependence of the rates of competing reactions suggest that the activation energy for insertion of SiH2into the C C I bond of CH3CIis, within experimental error, equal to that for SiH, insertion into the Si-H bond of SiH4.
carried out previously in our laboratory. It is of interest to determine whether SiH, will insert into the Studies of the infrared laser induced decomposition of pure C-CI bond of chloromethane and, if so, to learn what the charSiH4-SiF4, mixtures and SiH4-PH34 mixtures have shown that acteristics of this reaction are. Therefore, we have undertaken the predominant primary photodecomposition is to SiHz and H2. a study of the infrared laser photochemistry of SiH4-CH3CI Similarly, the homogeneous thermal decomposition of ~ i l a n e ~ - ~ mixtures, and in this paper report our results. also produces SiH, and Hz. It therefore appears that the infrared laser induced decomposition of SiH4is a good source of SiH, for Experimental Section study of the reactions of these labile molecules with other subThe infrared laser photodecompositions were carried out in a stances. cylindrical stainless steel cell having a diameter of 3.45 cm and Silylenes are known to insert into Si-H b o n d ~ . l - ~ . ~There -'~ a length of 15.5 cm. A pinhole leak, located in the wall of the is evidence that silylenes will insert into Si-OR Si-CI photolysis cell, lead directly into the ionization source of a bonds of halosilanes,'O,'l 0 - H bonds of alcohols9J9and water,I9 time-of-flight mass spectrometer. The pinhole was covered with and N-H bonds of primary and secondary amines.I9 Insertion a tube packed with glass wool to prevent the plugging of the into the strong H-H bond of hydrogen has also been reported, pinhole by the fine powder particles usually associated with deand kinetic studies have been carried out.'5-18 Kinetic studies of composition of silane. The ends of the photolysis cell were fitted the insertion reactions of SiH, into the P-H bond4 of PH3, the with NaCl windows sealed in place by O-ring supports. The cell Ge-H bond2' of GeH,, and the H-CI bond22of HCI have been was mounted so that the laser beam was perpendicular to the axis of the time-of-flight mass spectrometer. The source of infrared radiation was a C 0 2 TEA laser (Lumonics Research Ltd. Model 103-2) pulsed at a frequency of 0.5 ( I ) Longeway, P. A,; Lampe, F. W. J . A m . Chem. SOC.1981, 103,6813. Hz. All irradiations were carried out with an unfocused beam (2) OKeefe. J. F.; Lampe, F. W. Appl. Phys. Lett. 1983, 42, 217. and with the laser tuned to the P(20) line of the 10.6-km band, (3) Longeway, P. A,; Lampe, F. W. J . Phys. Chem. 1983, 87, 354. i.e., at 944.19 cm-I; this corresponds to a photon energy of 0.1 17 06 (4) Blazejowski, J. S.;Lampe, F. W. J . Photochem. 1982, 20, 9. eV. The average cross section of the beam was 5.66 cm2, and the (5) Purnell, J. H.; Walsh, R. Proc. R. SOC.London, Ser. A 1966, 293, 543. incident energy, as measured by a Gen Tec joulemeter and an (6) Newman, C. G.; O'Neal, H. E.; Ring, M. A,; Leska, F.; Shepley, N. Int. J . Chem. Kinet. 1979, I I , 1167. evacuated photolysis cell, ranged from 2.79 f 0.10 to 4.03 f 0.24 (7) Neudorjt, P.; Jodhan, A.; Strausz, 0. P. J . Phys. Chem. 1980,84, 338. J/pulse, resulting in an incident fluence range of 0.493-0.712 ( 8 ) Cochet, G.; Mellottee, H.; Delbourgo, R. J . Chem. Phys. 1974, 7 1 . J/cm2. The laser beam illuminated approximately 64% of the 1363. photolysis cell volume. (9) Atwell, W. H. U S . Patent 3478078, Nov 1969. During photolyses the concentrations of SiH4, C H Q , H2, CH4, ( I O ) Timms, P. L. Inorg. Chem. 1968, 7, 387. Si,H6, and SiH3C1were determined mass spectrometrically by ( 1 I ) Gaspar, P. P.; Herold, B. J. In Carbene Chemisfry,2nd ed.; Kirmse, measurement of the intensities of the ions at m / z 3 1, 50, 2, 16, W., Ed.; Academic Press: New York, 1971; p 504. 62, and 64, respectively. Calibrations for quantitative measure(12) Austin, E. R.; Lampe, F.W. J . Phys. Chem. 1976, 80, 2811. ments at the aforementioned masses, in which ion currents of (13) Bowrey. M.; Purnell, J. H. Proc. R . SOC.London, Ser. A 1971, 321, 341. reaction products are related to molecular concentrations, were (14) Sefcik, M. D.; Ring, M. A. J . Am. Chem. SOC. 1973, 95, 5168. carried out by using respective authentic samples. A pure sample (15) John, P.; Purnell, J. H. J . Chem. SOC.,Faraday Trans. 1 1973, 69, of SiH,CI was not available, and so initial rates of formation of 1455. this substance were calibrated by several methods22 described (16) Inoue, G.; Suzuke, M. Chem. Phys. Left. 1985, 122, 361. previously. ( 1 7 ) Jasinski, J. M. J . Phys. Chem. 1986, 90, 555. SiH,, CH3CI, H2, Ar, CH,, C(CH3),, and NO were all pur(18) Elley,C. D.; Rowe, M. C. A.; Walsh, R. Chem. Phys. Lett. 1986, 126, chased from Matheson, while Si,H, was supplied by Merck. SiF, 153. was obtained from the Linde Division, Union Carbide Corp. All (19) Gu, T.Y.; Weber, W. P. J . Organomet. Chem. 1980, 195, 29. compounds were subjected to freeze-pump-thaw cycles on a (20) Atwell, W. H.; Mahone, L. G.;Hayer, S. P.; Uhlmann, J . G. J . high-vacuum line prior to use. All gas mixtures were prepared Organomet. Chem. 1965, 18, 69. (21) Zhu, Pei-ran. Piserchio, M.; Lampe, F. W. J . Phys. Chem. 1985, 89, by using a Saunders-Taylor a p p a r a t ~ s . ~ ,
Introduction
5344. (22) Moore, C. B.; Biedrzcki, J.; Lampe, F. W. J . A m . Chem. SOC.1984, 106, 7761.
0022-3654/90/2094-4094$02.50/0
(23) Saunders, K N , Taylor, H A J Chem Phys 1941, 9, 616
0 1990 American Chemical Society
IR Laser Photochemistry of SiH4-CH3C1 Mixtures
The Journal of Physical Chemistry, Vol. 94, No. 10, 1990 4095
loo
%
P
e
W
.-
40 20
0
z ‘0 2.4
5
IO I5 2 0 25 30 35 40
r
u
A\:.-
0 1 2 3
lrrodiotion Time in Minuter
Figure 2. Dependence of ion currents for SiH,, CHI, SiH3CI,and Si2H6 on irradiation time. Fluence = 0.712 J/cmZ.
u
O”0
5
IO 15 20 25 30 35 4 0 P(SiH.1
in Torr
Figure 1. Absorption of energy by SiH, at a fluence of 0.493 J/cm2 as
a function of pressure: (a) percent of laser energy absorbed; (b) average number of photons per silane molecule in the beam path; 0,pure SiH,; ., equimolar SiH4-CH3CI mixture.
Results and Discussion Absorption of Energy. The P(20) line of the 10.6-pm band from the C 0 2 laser (944.19 cm-I), as shown by D e ~ t s c h , ~closely , matches an R-branch transition in the v4 mode of SiH, (944.21 cm-’) and thus is an efficient frequency at which to carry out the photodecomposition. I n Figure l a , the percent absorption of the laser beam at a fluence of 0.493 J/cm2 is plotted vs the partial pressure of silane, while Figure 1 b shows the pressure dependence of 8, the average number of photons absorbed per molecule. As seen in Figure la, the percent energy absorption is enhanced by the presence of an equal amount of chloromethane. In Figure 1b, for pure SiH,, 0 increases to a maximum at a pressure of 20 Torr and then decreases. At low partial pressures of SiH,, for a 1:l mixture of SiH, with CH3CI,8 is much higher compared to that of pure silane and increases with an increase in pressure to a maximum at about IO Torr (SiH,) and then decreases. Although energy absorption is enhanced by the presence of CH3CI, chloromethane does not absorb radiation at this frequency. This indicates that CH3CISiH, collisions redistribute vibrational energy efficiently, thereby continuously providing SiH, molecules in low v4 states. This enhancement in energy absorption in the presence of foreign gases has been previously o b s e r ~ e d . ’ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ Photolysis at a fluence of 0.71 2 J/cmZ were carried out on gas mixtures in which the pressure of SiH, was maintained at 45 Torr and the partial pressure of CH3CI was varied from 0 to 45 Torr. Over this range of CH3CI partial pressure 0 increased monotonically from 1.44 to 1.66. Products of the Reaction. Continuous mass spectrometric monitoring of the reaction mixture as a function of time, or number of laser pulses, leads us to conclude that both SiH, and CH3CI are reacted, although quantitative measurements of the chloromethane depletion were not possible due to the low conversion. The gaseous products observed are H,, CH,, Si2H6,and SiH3C1, with trace amounts of Si3H8and perhaps CH3SiH2CI,although ion intensities for the latter were too low for quantitative measurement. The very low amounts of this latter product were unexpected because, based upon the strong evidence for SiH, (24) Deutsch, T. F. J . Chem. Phys. 1979, 70, 1187. (25) Olszyna, K. J.; Grundwald, E.; Keehn, P. M.; Anderson, S.P. Terrahedron Lett. 1977, 19, 1609. ( 2 6 ) Ronn, A. M. Spectrosc. Letr. 1975, 8, 303.
insertion into the H-CI bond in the IR photochemistry of SiH,-HCI mixtures:2 we anticipated that CH3SiH2C1would be the major reaction product rather than CH4 and SiH3C1. Experiments carried out using small amounts of NO, as a monoradical scavenger, added to a 1:l mixture of SiH, and CH3C1 were negative in the detection of methyl radicals. If methyl radicals were produced in the photolysis, they would have been scavenged by the nitric oxide, the production of methane would be inhibited, and C H 3 N 0 would have been ~bserved.~’ As is usual in silane decomposition, a brown solid product containing silicon, hydrogen, and, under some conditions, chlorine was also produced. The extent of formation of the solid silicon hydride depends sharply on the pressure of SiH,. At the lowest pressures of SiH, employed (25-30 Torr) the solid appears as a poorly adherent film on the cell windows and walls, while at the higher pressures the solid appears immediately as suspended particulate matter in the gas phase of the photolysis cell. As may be seen in Figure 2, the identical shapes of the recorder tracings of the ion currents for CH4+ ( m / z = 16), Si2H6+( m / z = 6 2 ) , and SiHCI+ ( m / z = 64) indicate that all these reaction products are formed simultaneously and concurrently with the depletion of the reactant SiH, (SiH3+, m / z = 31). This means that CH,, SizH6, and SiH3C1 are all primary products of the infrared photodecomposition of SiH, in the presence of CH3C1 and are not formed by way of further reaction of some product. In our definition here of primary product, we mean stable product since our time resolution does not permit us to see the attainment of steady-state concentration of reactant transients such as SiH2. Mechanism of the Photochemical Reaction. We consider the simultaneous formation of products, Le., Si2H6,CH,, and SiH3C1, from the infrared laser photolysis of SiH4 to be a direct result of the competition of SiH, and CH3CI for SiH2 molecules formed in the primary photodecomposition. Therefore, we represent the mechanism for formation of the primary products H2, CH,, SizH6, and SiH3C1 by the reactions shown in (1)-(7). SiH, + nhv SiHz + H 2 (1)
-
+ + + + -+ +- -+
SiH2 + SiH, SiH,
CH3C1
CH3SiH2C1*
(2)
CH3SiH,CI*
(3)
SiHCl
CH,
SiH, = SizH5C1*
SiHCl
Si2H5CI* Si2H5C1*
Si2H6
H,
Si2H5CI* M
SiH,
SiH3C1
Si2H3C1
Si2H5Cl
solid
(4)
(5) (6) (7)
M
(8) The formation of Si2H6is more accurately described by eqs 2a-2c; however, results from the study of SiH,-HCl mixturesz2 in the same pressure range show Si2H6 formation to be in the (27) Maschke, A.; Shapiro, B. S.; Lampe, F. W . J . Am. Chem. Soc. 1964, 86, 1929.
4096
The Journal of Physical Chemistry, Vol. 94, No. 10, 1990
Moore and Lampe
-* I
3
0
2
-
'0
.2 .4
7
393K
.6
.8
'0
I
.2
.4
.6
8
I
10 \
-*
I
'0
30
40
50
in Torr
Figure 5. Dependence of the initial rate of decomposition of SiH, on the partial pressure of CH,CI added: ,. 30 Torr of SiH,; 0 , 4 5 Torr of SiH,. Fluence = 0.712 J/cm2.
3 E 2 K
20 P(CH,CI)
.6 .8 CCH,CIl /CSiH,I
I
.2 .4
'0
.2 . 4
.6
.8
I
CCH,Cll/CSiH,l
I
-6.1
6:
Figure 3. Dependence of the initial rate ratio R(CH,)/R(Si,H,) on partial pressure of CH3CI at various temperatures (P(SiH,) = 45 Torr). Fluence = 0.712 J/cm2.
0.4
0.220 25 0.0
30
~~
35
40
P(SiH,)
"; 2.2
45
50
55
in Torr
Figure 6. Dependence of the initial rate of decomposition of SiH4on the partial pressure of SiH,, for a 1:l mixture of SiH, and C H Q . Fluence = 0.712 J/cmZ. 2.4
2.8
2.6
4x
3D
3.2
IO'
Figure 4. Arrhenius plots of data in Figure 3: Le., log (d[R(CH,)/R(Si,H,)]/d[CH,CI]) vs 1/T.
second-order region, and therefore, (2) is sufficiently accurate under our conditions. SiH,
+ SiH,
+
Si2H6* Si2H6*
-
Si2H6*
@a)
+ H, Si2H6 + M*
Ob)
SiH,SiH
M
+
(2c)
Comparison of the reaction rates of (2) and (3) was accomplished by monitoring the rates of production of methane and disilane. Although chlorosilane is a major product, we believe it is formed by the reaction of a secondary silylene product, SiHCI, with silane. There are further complicating reactions of SiHCI, discussed later on, which make chlorosilane a poor choice for the monitoring of the rate of reaction 3. A standard kinetic treatment of this mechanism leads to the following expression for the ratio of the initial rate of CH, formation to that of Si2H6: R(CH4) - k3[CH3CIl -R(Si2H6)
k2[SiH4]
provided the ambient temperature in such experiments involving infrared multiple-photon decompositionand the attendant transient heating has any significance, we conclude that the temperature coefficient of the ratio k3/k2 is zero. As we have discussed in a previous paper,,, we believe the ambient temperature does play a significant role because the unimolecular decomposition of SiH, and the subsequent reactions of SiH2 will occur on a time scale that is very short compared with V T, R relaxation times and with cooling at the walls.28 Hence, we conclude from our data that E , = E,. Moreover, recent measurements have demonstrated that k , is so close to the collision rate coefficient that E2 (and hence E,) must be very close to zero. In Figure 5 the initial rates of decomposition of both 30 and 45 Torr of silane are plotted vs the partial pressure of C H Q added. It is evident that an increase in the partial pressure of CH,CI has the effect of decreasing the initial decomposition rate for silane. This decrease in the rate of silane decomposition is most likely due to vibrational deactivation of SiH4* formed initially by absorption of infrared photons. Thus, reaction 1 in the mechanism is actually comprised of several steps, namely, (la), (1 b), and (IC). The role of CH3C1 in Figure 5 is to deactivate SiH4*, as in eq IC.
-
SiH, (9)
This expression predicts, of course, that the ratio of rates should vary linearly with the concentration ratio [CH,CI]/[SiH,]. I n agreement with (9),the data in Figure 3 show a linear dependence of the ratio of initial rates, R(CH4)/R(Si2H6),on the concentration ratio [CH,CI]/[SiH,] over the temperature range 295-428 K. The slopes of the lines in Figure 3 are the rate constant ratios, k 3 / k 2 ,and the insensitivity of this ratio to temperature is demonstrated by the Arrhenius plot in Figure 4. Thus,
+ nhv
+
SiH4*
+ H, SiH4*(n